JPH0240442A - Air conditioner - Google Patents

Abstract

PURPOSE:To prevent water and ice from dispersing from fins in an air conditioner that performs off-cycle defrosting operation, by turning down the driving force of a fan motor so as to operate at weak wind state. CONSTITUTION:When frosting or icing on fins occurs, and the temperature of a cooler reaches the set temperature, a thermostat 26L becomes OFF, and coils of a compressor magnetic contactor 52C and an auxiliary relay X are demagnetized so that a compressor is stopped. In addition, the contact x of the auxiliary relay X is changed from notch A to notch B so that off-cycle defrosting operation takes place. And the driving force of a fan motor MF is lowered to operate at weak wind state. Therefore, water and ice can be prevented from dispersing.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to something that prevents water and ice from scattering from the fins of a cooler during off-cycle defrosting of an air conditioner.

[Conventional technology]

Conventionally, the circuit shown in FIG. 4 is the most suitable configuration for an air conditioner.

In the figure, P is a power supply supplied to each part of the air conditioner, SW is an operation switch for starting and stopping the operation of the air conditioner, 52F is a fan motor electromagnetic contactor for driving the fan motor, 52C is a compressor electromagnetic contactor for driving the compressor, 26L is a thermostand that senses the temperature of the cooler, and this thermostat 26L
is turned off at -800 and turned on at +8@C.

In this air conditioner, when the operation switch SW is turned on, the coil of the fan motor electromagnetic contactor 52F is excited, and this a contact is turned on to drive the fan motor. Furthermore, since the thermostat 26L is on, the coil of the compressor electromagnetic contactor 52C is excited, the compressor is driven, and cooling operation is performed. Then, as the suction temperature of the cooler decreases, the suction pressure decreases, and the surface temperature of the fins of the cooler also decreases, causing frost or ice to form on the cooler. Furthermore, the temperature of the cooler decreases and the set temperature (-86
0), the thermostat 26L is turned off, the coil of the compressor electromagnetic contactor 52C is demagnetized, and the compressor is stopped. However, even after stopping, the fan motor continues to operate, blowing air into the cooler and melting the frost or ice (
This is called off-cycle defrost). When all this frost or ice melts, the temperature of the cooler increases,
When the reset temperature (+8”C) is reached, the thermostat turns on to 26L.
is turned on, the coil of the compressor electromagnetic contactor 52C is excited, and the compressor is brought into operation again, and thereafter the above-described cycle is repeated.

[Problem to be solved by the invention]

However, since conventional air conditioners are configured as described above, when the cooler freezes and starts off-cycle defrost, the passage area of the unfrozen part of the cooler through which the air from the fan motor passes is The speed of the air passing through the pipe increases, and the amount of drain temporarily increases when the frozen ice melts, resulting in the problem of water and ice scattering from the fins.

The present invention was made to solve these problems, and an object of the present invention is to provide an air conditioner that can perform off-cycle defrosting without causing water or ice to scatter.

[Means to solve the problem]

The present invention lowers the driving force of the fan motor during off-cycle defrost to blow a breeze.

[For production]

During off-cycle defrost, the speed and wind force of the air sent out from the fan motor decreases.

〔Example〕

Next, the present invention will be explained with reference to the drawings.

FIG. 3 is an overall circuit diagram representing one embodiment of the present invention,
The same reference numerals are used for the same or corresponding parts as in FIG. 4, and the explanation thereof will be omitted. Further, FIG. 1 is a circuit diagram showing a fan motor MF connected to a contact 52f of a fan motor electromagnetic contactor 52F, and FIG. 2 is a circuit diagram showing details of the inside of this fan motor.

In the same figure, X is an auxiliary relay, and this auxiliary relay
The contact X consists of a C contact, and is normally connected to the notch A (normal notch) on the opposite side of the diagram.As will be described later, during off-cycle defrost, the notch is Switched to B (breeze notch). Further, the fan motor MF is composed of a main coil 1° and auxiliary coils 2 and 3, and a driving capacitor C is connected to this fan motor MF.

In such a configuration, when the operation switch SW is turned on, the coil of the fan motor electromagnetic contactor 52F is excited. Furthermore, since the thermostat 26L is on, the compressor electromagnetic contactor 52C and the coil of the auxiliary relay X are excited, and the contact X is switched upward in the figure. Therefore, the fan motor MF is connected to the notch A and normal operation is performed, and at the same time, the compressor is also started to operate. Then, as the suction temperature of the cooler decreases, the suction pressure decreases, and the temperature of the surface of the fins of the cooler also decreases, causing frost or ice to form on the cooler. Furthermore, when the temperature of the cooler decreases and reaches the set temperature (-8"C), the thermostat l-26L turns off, and the compressor magnetic contactor 52
The coils of C and auxiliary relay X are demagnetized and the compressor is stopped.

Further, the contact X of the auxiliary relay X is switched to the lower side in the figure, and the notch A is switched to the notch B, thereby performing the off-cycle defrost described above. At this time, the passage area of the non-frozen part of the cooler through which the air from the fan motor MF passes is small (but the air volume is small), so the wind speed and wind force of the air passing through do not increase, and the fins of the cooler It becomes possible to melt frost and ice without causing water or ice to scatter.

〔Effect of the invention〕

As explained above, the present invention has the following advantages: - By lowering the driving force of the fan motor during off-cycle defrost and making the air blown into a light breeze, the wind speed and wind power of the air sent out from the fan motor during off-cycle defrost are reduced, thereby cooling the air. It has the effect of preventing water and ice from scattering from the fins of the container (off-cycle defrosting can be performed).

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram representing one embodiment of the present invention, and FIG.
FIG. 3 is an overall circuit diagram in which the circuit shown in FIG. 1 is used, and FIG. 4 is a circuit diagram of a conventional air conditioner. P...tl, B, MF...fan motor, A. B...notch, 52F...magnetic contactor for fan motor, 52f...contact of electromagnetic contactor 52F for fan motor, 52C...magnetic contactor for compressor, X...auxiliary relay, X ...Auxiliary relay X contact, 26L...Thermostat, SW...Operation switch. Agent Masuo Oiwa 1st

Claims (1)

[Claims] An air conditioner that performs off-cycle defrost by rotating a fan motor to blow air to a cooler, characterized in that during the off-cycle defrost, the driving force of the fan motor is reduced to make the air blown into a breeze. Machine.